F3l: an automated and secure function-level low-overhead labeled encrypted traffic dataset construction method for IM in Android

IF 3.9 4区 计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS Cybersecurity Pub Date : 2024-01-01 DOI:10.1186/s42400-023-00185-6
Keya Xu, Guang Cheng
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Abstract

Fine-grained function-level encrypted traffic classification is an essential approach to maintaining network security. Machine learning and deep learning have become mainstream methods to analyze traffic, and labeled dataset construction is the basis. Android occupies a huge share of the mobile operating system market. Instant Messaging (IM) applications are important tools for people communication. But such applications have complex functions which frequently switched, so it is difficult to obtain function-level labels. The existing function-level public datasets in Android are rare and noisy, leading to research stagnation. Most labeled samples are collected with WLAN devices, which cannot exclude the operating system background traffic. At the same time, other datasets need to obtain root permission or use scripts to simulate user behavior. These collecting methods either destroy the security of the mobile device or ignore the real operation features of users with coarse-grained. Previous work (Chen et al. in Appl Sci 12(22):11731, 2022) proposed a one-stop automated encrypted traffic labeled sample collection, construction, and correlation system, A3C, running at the application-level in Android. This paper analyzes the display characteristics of IM and proposes a function-level low-overhead labeled encrypted traffic datasets construction method for Android, F3L. The supplementary method to A3C monitors UI controls and layouts of the Android system in the foreground. It selects the feature fields of attributes of them for different in-app functions to build an in-app function label matching library for target applications and in-app functions. The deviation of timestamp between function invocation and label identification completion is calibrated to cut traffic samples and map them to corresponding labels. Experiments show that the method can match the correct label within 3 s after the user operation.

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F3l:用于安卓即时通讯的自动化安全功能级低开销标记加密流量数据集构建方法
细粒度功能级加密流量分类是维护网络安全的重要方法。机器学习和深度学习已成为流量分析的主流方法,而标记数据集的构建是基础。安卓占据了移动操作系统市场的巨大份额。即时通讯(IM)应用是人们交流的重要工具。但这类应用功能复杂,切换频繁,因此很难获得功能级标签。安卓系统中现有的功能级公共数据集既稀少又嘈杂,导致研究停滞不前。大多数标签样本都是通过 WLAN 设备采集的,无法排除操作系统后台流量的影响。同时,其他数据集需要获得 root 权限或使用脚本模拟用户行为。这些收集方法要么破坏了移动设备的安全性,要么粗粒度地忽略了用户的真实操作特征。之前的工作(Chen et al. in Appl Sci 12(22):11731, 2022)提出了在安卓系统应用层运行的一站式自动加密流量标签样本采集、构建和关联系统A3C。本文分析了IM的显示特点,提出了一种功能级低开销的Android系统加密流量标签数据集构建方法F3L。A3C 的辅助方法在前台监控安卓系统的用户界面控件和布局。它针对不同的应用内功能,选择其中的属性特征字段,为目标应用和应用内功能建立应用内功能标签匹配库。校准功能调用与标签识别完成之间的时间戳偏差,以切割流量样本并将其映射到相应的标签。实验表明,该方法能在用户操作后 3 秒内匹配出正确的标签。
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来源期刊
Cybersecurity
Cybersecurity Computer Science-Information Systems
CiteScore
7.30
自引率
0.00%
发文量
77
审稿时长
9 weeks
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